Phase controller and phase controlling method for antenna array, and communication apparatus using the same

ABSTRACT

A phase controller for an antenna array includes a determination circuit, determining a direction index of the antenna array, and calculating a phase index according to the direction index according to a congruence modulo equation; a switching box, selecting L first frequency signals with L different first phases among K first frequency signals with K different first phases according to the phase index, wherein L and K are integer larger than 1, and L is not larger than K; and a frequency synthesizing module, comprising L phase-coherent PLL frequency synthesizers for receiving the L first frequency signals with the L different first phases to generate L second frequency signals with L different second phases to L antennae of the antenna array, wherein a second frequency of the second frequency signals is larger than a first frequency of the first frequency signals.

FIELD OF THE INVENTION

The present disclosure relates to a communication apparatus having aphase controller or executing a phase controlling method for an antennaarray with a plurality of antennae, and in particular to a communicationapparatus having a phase controller or executing a phase controllingmethod for an antenna array by using multiple phase-coherent phaselocked loop (PLL) frequency synthesizers based upon a congruence moduloequation.

BACKGROUND OF THE INVENTION

An antenna array with a plurality of antennae is widely used in acommunication apparatus, such as a transceiver, a transmitter or areceiver, and the phase of the antenna array can be controlled to have aspecific main direction for radiating signals (i.e. the radiation fieldpattern can be controlled). The conventional controlling manner for theantenna array can be implemented by a plurality of phase shifters or aplurality of PLLs, wherein each neighbor two of the PLLs are coupled toeach other.

Referring to FIG. 1A, FIG. 1A is a schematic diagram of a conventionalphase controller used in a communication apparatus. In FIG. 1A, thecommunication apparatus 1 comprises a plurality of phase shifter PS_1through PS_n and a plurality of antennae ANT_1 through ANT_n, wherein nis an integer larger than 1. The phase shifters PS_1 through PS_n form aconventional phase controller, and the antennae ANT_1 through ANT_n forman antenna array, wherein each neighbor two of the antennae ANT_1through ANT_n have a separated distance d.

Each of the phase shifters PS_1 through PS_n receives a firsttransmitted signal and shifts a phase of the transmitted signal, so asto generate a plurality of transmitted signals with different phases ϕ₀through ϕ_(n) to the corresponding one of the antennae ANT_1 throughANT_n. The phases ϕ₀ through ϕ_(n) can determine the angle θ (inrespective to a vertical axis y), or a main radiating direction MD ofthe antennae array, and the distance d between wave fronts of eachneighbor two of the antennae ANT_1 through ANT_n is related to the angleθ of the antennae array. Therefore, by controlling the phases ϕ₀ throughϕ_(n), the radiation field pattern of the antenna array can bedetermined.

Next, referring to FIG. 1B, FIG. 1B is a schematic diagram of anotherone conventional phase controller used in a communication apparatus. Thedifference between the communication apparatuses 1′ and 1 is that theconfiguration of the phase shifters PD_1 through PD_n of thecommunication apparatus 1′ is not the same as that of the phase shiftersPS_1 through PS_n of the communication apparatus 1. Specifically, thecommunication apparatus 1′ adopts the step phase shift configuration ofthe phase shifters PD_1 through PD_n, each of the phase shifters PD_2through PD_n receives the transmitted signal being shifted with thephase Δϕ by the previous one phase shifters PD_1 through PD (n−1), andthe phase shifter receives the transmitted signal. By controlling thephase Δϕ, the radiation field pattern of the antenna array can bedetermined.

The shifted phases of the phase shifters in different frequencies arenot identical to each other, and the phase shifters have problems ofphase imbalance and gain dis-match. Thus, the transmitted signals whichare expected to have fixed differential phases may have phase errors andamplitude errors, and it causes the desired radiation filed pattern ofthe antenna array is not correct.

As mentioned above, another one conventional controlling manner for theantenna array adopts a plurality of PLLs, wherein each neighbor two ofPLLs are coupled, and the control signals can be input into the voltagecontrolled oscillators (VCOs) of the PLLs to control the phase of theantenna array. However, this conventional controlling manner for theantenna array does not comprise a reference signal source with the highprecision and the low phase noise, and it uses the coupled VCOs forinjection and locking, thus resulting that the high phase noise mayexists in the output signals of the VCOs, and the output frequency isnot accurate.

SUMMARY OF THE INVENTION

An objective of the present disclosure is to provide a communicationapparatus having a phase controller or executing a phase controllingmethod for an antenna array with a plurality of antennae, so as to havethe low phase and amplitude error, the high frequency precision and thecorrect desired radiation field pattern.

To achieve at least the above objective, the present disclosure providesa phase controller for an antenna array, comprising: a determinationcircuit, determining a direction index of the antenna array, andcalculating a phase index according to the direction index according toa congruence modulo equation; a switching box, connected to thedetermination circuit, selecting L first frequency signals with Ldifferent first phases among K first frequency signals with K differentfirst phases according to the phase index, wherein L and K are integerlarger than 1, and L is not larger than K; and a frequency synthesizingmodule, connected to the switching box, comprising L phase-coherent PLLfrequency synthesizers for receiving the L first frequency signals withthe L different first phases to generate L second frequency signals withL different second phases to L antennae of the antenna array, wherein asecond frequency of the second frequency signals is larger than a firstfrequency of the first frequency signals; wherein the switching boxcomprises: a plurality output lines IN_0, IN_1, . . . , IN_K−1; aplurality of input lines OUT_0, OUT_1, . . . , OUT_K−1; and a pluralityof switches r₀, r₁, r₂, . . . , r_(LK-1), first ends of the switchesr_(nK) through r_((n+1)K-1) are connected to the output line OUT_n, andsecond ends of the switches r_(nK) through r_((n+1)K-1) are connected tothe input lines IN_0 through IN_K−1, wherein n is an integer from 0through L−1; wherein the switches r₀, r₁, r₂, . . . , r_(LK-1) areturned on or off according to the phase index, so as to select the Lfirst frequency signals with the L different first phases among the Kfirst frequency signals with the K different first phases; wherein thephase-coherent PLL frequency synthesizer comprises: a mixer, receiving acorresponding one of the L first frequency signals with the L differentfirst phases and a frequency divided signal; a low pass filter,connected to the mixer, filtering an output signal of the mixer; avoltage controlled oscillator, connected to the low pass filter,generating a corresponding one of the L second frequency signals withthe L different second phases according to a control voltage output fromthe low pass filter; and a frequency divider, connected to the mixer andthe voltage controlled oscillator, generating the frequency dividedsignal according to the corresponding second frequency signal with thesecond phase.

To achieve at least the above objective, the present disclosure providescommunication apparatus, comprising: a multi-phase signal generatingcircuit, providing K first frequency signals with K different firstphases; L antennae, forming an antenna array; and the above phasecontroller for the antenna array, connected between the multi-phasesignal generating circuit and the L antennae.

To achieve at least the above objective, the present disclosure providesphase controlling method for an antenna array, comprising: determining adirection index of the antenna array; calculating a phase indexaccording to the direction index according to a congruence moduloequation; selecting L first frequency signals with L different firstphases among K first frequency signals with K different first phasesaccording to the phase index, wherein L and K are integer larger than 1,and L is not larger than K; and generating L second frequency signalswith L different second phases to L of antennae of the antenna arrayaccording to the L first frequency signals with the L different firstphases by using L phase-coherent PLL frequency synthesizers, wherein asecond frequency of the second frequency signals is larger than a firstfrequency of the first frequency signals.

In an embodiment of the present disclosure, wherein the K differentfirst phases are 0, δϕ, 2δϕ, . . . , (K−1)δϕ, the L different firstphases are 0, Δθ, 2Δθ, . . . , (L−1)Δθ, the second different phases are0, Δϕ, 2Δϕ, . . . , (L−1)Δϕ, δϕ is a phase resolution and equals to2π/K, Δϕ equals to kδϕ, k is the direction index being an integer, Δθequals to lδϕ, l is the phase index being an integer, and the congruenceequation is Ml≡k(mod K) if M and K are mutually prime integers, whereinM is a frequency divisor.

In an embodiment of the present disclosure, wherein the K differentfirst phases are 0, δϕ, 2δϕ, . . . , (K−1)δϕ, the L different firstphases are 0, Δθ, 2Δθ, . . . , (L−1)Δθ, the second different phases are0, Δϕ, 2Δϕ, . . . , (L−1)Δϕ, δϕ is a phase resolution and equals to2π/K, Δϕ equals to kδϕ, k is the direction index being an integer, Δθequals to lδϕ, l is the phase index being an integer, and the congruenceequation is Pl≡Qk(mod QK) if M=P/Q, and P and Q are mutually primeintegers, wherein M is a frequency divisor.

In an embodiment of the present disclosure, the multi-phase signalgenerating circuit comprises: a voltage controlled delay line, having aplurality of delay units connected in series, receiving a referenceclock signal; a phase detector, connected to the voltage controlleddelay line, comparing phases of the reference signal and an outputsignal of the voltage controlled delay line to output a comparisonsignal; and a low pass filter, connected to the phase detector and thevoltage controlled delay line, filtering the comparison signal; whereina delay time of the delay units is controlled by an output signal of thelow pass filter, and input ends of the delay units are used to outputthe K first frequency signals with the K different first phases.

In an embodiment of the present disclosure, the multi-phase signalgenerating circuit comprises: a phase-frequency detector, receiving areference clock signal and a frequency divided signal, and comparingfrequencies and phases of the reference clock signal and the frequencydivided signal to output a comparison signal; a charge pump, connectedto the phase-frequency detector, raising a voltage of the comparisonsignal; a loop filter, connected to the charge pump, filtering an outputsignal of the charge pump; a quadrature voltage controlled oscillator,connected to the loop filter, receiving an output signal of the loopfilter to generate oscillating signal with quadrature phases; afrequency divider, connected to the quadrature voltage controlledoscillator, receiving one of the oscillating signal with the quadraturephases to generate the frequency divided signal; and an injection-lockedfrequency divider, connected to the quadrature voltage controlledoscillator, receiving the oscillating signals with the quadrature phasesto generate the K first frequency signals with the K different firstphases.

In an embodiment of the present disclosure, the communication apparatusfurther comprises: a L-path front-end circuit module, comprising Lfront-end circuits, wherein the front-end circuit comprises: a mixer,mixing a transmitted intermediate frequency signal with a correspondingone of the L second frequency signals with the L different secondphases; a filter, connected to the mixer, filtering an output signal ofthe mixer; and a power amplifier, connected to the filter, amplifying anoutput signal of the filter, so as to generate an output signal to thecorresponding antenna.

In an embodiment of the present disclosure, the communication apparatusis a receiver, a transmitter or a transceiver.

In an embodiment of the present disclosure, the direction index isrelated to a phase, a main radiating direction and a radiation fieldpattern of the antenna array.

To sum up, compared with the conventional phase controller or phasecontrolling method for the antenna array, the present disclosure hasbenefits of the low phase and amplitude error, the high frequencyprecision and the correct desired radiation field pattern.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1A is a schematic diagram of a conventional phase controller usedin a communication apparatus;

FIG. 1B is a schematic diagram of another one conventional phasecontroller used in a communication apparatus;

FIG. 2 is a block diagram of a phase-coherent PLL frequency synthesizeraccording to an embodiment of the present disclosure;

FIG. 3 is a block diagram of a communication apparatus according to anembodiment of the present disclosure;

FIG. 4 is a circuit diagram of a switching box according to anembodiment of the present disclosure;

FIG. 5 is a block diagram of a multi-phase signal generating circuitaccording to an embodiment of the present disclosure;

FIG. 6 is a block diagram of a multi-phase signal generating circuitaccording to another one embodiment of the present disclosure;

FIG. 7 is a flow chart of a phase controlling method for an antennaarray according to an embodiment of the present disclosure;

FIG. 8A is a schematic diagram of radiation field patterns of antennaarray with different direction indices while the phase controller orphase controlling method for the antenna array according to anembodiment of the present disclosure is used; and

FIG. 8B is a schematic diagram of radiation field patterns of antennaarray with different direction indices while the phase controller orphase controlling method for the antenna array according to anembodiment of the present disclosure is used.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

To make it easier for the examiner to understand the objects,characteristics and effects of this present disclosure, embodimentstogether with the attached drawings for the detailed description of thepresent disclosure are provided.

An embodiment of the present disclosure provides a phase controller foran antenna array in a communication apparatus. Specifically, a directionindex of the antenna array (p.s. the direction index is related to aradiation field pattern, a main radiating direction or a phase of theantenna array) is determined according to an actual demand, and then thedirection index can be used to calculate a phase index based upon acongruence modulo equation. Based upon the calculated phase index, Lfirst frequency signals with L different first phases are selected fromK first frequency signals with K different first phases (p.s. K and Lare integers larger than 1, and L is not larger than K), and then the Lfirst frequency signals with the selected L different first phases areinput to L phase-coherent PLL frequency synthesizers to generate Lsecond frequency signals with L different second phases respectively,wherein the second frequency signals have a second frequency larger thana frequency of the first frequency signals. Next, the L second frequencysignals with the L different second phases are transmitted to Lfront-end circuits connected to L antennae to control the main radiatingdirection of the antenna array formed by the L antennae. In addition, aphase controlling method for an antenna array deduced from the conceptof the above phase controller for the antenna array is also disclosed.

Referring to FIG. 2, FIG. 2 is a block diagram of a phase-coherent PLLfrequency synthesizer according to an embodiment of the presentdisclosure. The phase-coherent PLL frequency synthesizer 2 comprises amixer 21, a low pass filter (LPF) 22, a VCO 23 and a frequency divider24, wherein the mixer 21 is connected to the LPF 22 and the frequencydivider 24, and the VCO 23 is connected to the LPF 22 and the frequencydivider 24.

A first frequency signal with a first phase (i.e. Ai cos(ωreft+θi)) ismixed with a frequency divided signal (i.e. GdA0 cos((ωRFt/M)+(ϕi/M)))by the mixer 21, and the mixer 21 can be the multiplier as known by theperson with ordinary skill in the art. The LPF 22 is used to filter theoutput signal of the mixer 21 to generate a control voltage vc(t) to theVCO 23. The VCO 23 generate a second frequency signal with a secondphase (i.e. Ao cos(ωRFt+ϕi)). The second frequency signal with thesecond phase is input to the frequency divider 24 to generate frequencydivided signal.

All above variables are illustrated as follows, Ai is an amplitude ofthe first frequency signal, ωref is a first frequency of the firstfrequency signal, t is time, θi is the first phase of the firstfrequency signal, ωRF is a second frequency of the second frequencysignal, ϕi is a second phase of the second frequency signal, Ao is anamplitude of the second frequency signal, and M is a frequency divisorof the frequency divider 24.

It is noted that, cos(ωRFt+ϕi) can be identical to cos(ωRFt+ϕi+2πm),wherein m is an integer. When the first frequency ωref equals to ωRF/M(i.e. ωref=ωRF/M) and Mθi equals to ϕi+2πm (i.e. Mθi=ϕi+2πm), the phaselocking can be performed. The phase locking condition can be expressedby a congruence modulo equation Mθiϕi(mod 2π), wherein the abovecongruence modulo equation means the remainders of Mθi and ϕi divided by2π are the same one.

Next, referring to FIG. 3, FIG. 3 is a block diagram of a communicationapparatus according to an embodiment of the present disclosure. Thecommunication apparatus 3 comprises a multi-phase signal generatingcircuit (not shown in FIG. 3, but shown in FIG. 5 or FIG. 6), a phasecontroller 31 for an antenna array, the antenna array formed by theantennae ANT_0 through ANT (L−1) and L-path front-end circuit module 32.The phase controller 31 is connected to antenna array via the L-pathfront-end circuit module 32. The phase controller 31 is used to controlthe phase of the antenna array, such that the antenna array can have adesired radiation field pattern (i.e. a desired main radiating directionor a desired phase).

The phase controller 31 can receive K first frequency signals with Kdifferent first phases (i.e. B cos(ωreft), B cos(ωreft+δϕ), Bcos(ωreft+2δϕ), . . . , B cos(ωreft+(K−1)δϕ) generated from themulti-phase signal generating circuit (shown in FIG. 5 or FIG. 6) anduse portions of them to generate L second frequency signals with Ldifferent second phases (i.e. A cos(ωRFt), A cos(ωRFt+Δϕ), Acos(ωRFt+2δϕ), . . . , A cos(ωRFt+(L−1)Δϕ)) to the L-path front-endcircuit module 32, so as to control the phase of the antenna array,wherein A and B are amplitudes of the second and first frequencysignals, δϕ is a phase resolution.

Specifically, the phase controller 31 comprises a switching box 311, afrequency synthesizing module 312 and a determination circuit 313,wherein the frequency synthesizing module 312 has L phase-coherent PLLfrequency synthesizers. The L-path front-end circuit module has Lfront-end circuits, the nth one of the front-end circuits is formed by amixer 321_n, a filter 322_n, and a power amplifier (PA) 323_n, wherein,n is an integer from 0 through L−1. The mixer 321_n is connected to thefilter 322_n, the filter 322_n is connected to the PA 323_n, and the PA323_n is connected to the antenna ANT_n.

The determination circuit 313 determines a direction index k andaccordingly calculates a phase index l according to the direction indexk based upon of a congruence modulo equation. The determination circuit313 further generates controls signals to the switching box 311. Theswitching box 311 selects L first frequency signals with L differentfirst phases (i.e. B cos(ωreft), B cos(ωreft+Δθ), B cos(ωreft+2Δθ), . .. , B cos(ωreft+(L−1)Δθ)) among the K frequency signals with the Kdifferent first phase according to the control signals (i.e. the controlsignals are related to the phase index l). The first frequency signalswith the L different first phases are respectively input to the Lphase-coherent PLL frequency synthesizers of the frequency synthesizingmodule 312, so as to generate the L second frequency signals with the Ldifferent second phases.

Next, the nth one of second frequency signals (i.e. A cos(ωRFt+nΔϕ) ismixed with the transmitted intermediate frequency (IF) signal by themixer 321_n. The output signal of the mixer 321_n is filtered andamplified by the filter 322_n and the PA 323_n. Finally, the outputsignal is of the PA 323_n is transmitted to the antenna ANT_n. It isnoted that, if the IF shifting is not required, the L-path front-endcircuit module 32 can be removed.

In the embodiment, the desired second phase ϕi is nΔϕ, and the firstphase θi to be found is nΔθ, and thus the above congruence moduloequation can be expressed as MΔθ≡Δϕ(mod 2π). When the phase resolutionδϕ is designed to be divisible for 2π (i.e. δϕ=2π/K), the desired phaseΔϕ of can be kδϕ (i.e. Δϕ=kδϕ, and k is the direction index being aninteger), the phase Δθ to be solved is (i.e. i.e. Δθ=lδϕ, and l is thephase index being an integer), and the above congruence equation can beexpressed as Ml≡k(mod K), wherein M and K are mutually prime integers.That is, when the direction index k is determined by the desired phaseΔϕ, the phase index l can be obtained from the congruence equationMl≡k(mod K) if M and K are mutually prime integers.

It is noted that, if M is not an integer (i.e. the phase-coherent PLLfrequency synthesizer is a fractional-N phase-coherent PLL frequencysynthesizer), the above congruence equation can be expressed asPl≡Qk(mod QK), wherein M equals to P/Q (i.e. M=P/Q), and P and Q aremutually prime integers. That is, when the direction index k isdetermined by the desired phase Δϕ, the phase index l can be obtainedfrom the congruence equation Pl≡Qk(mod QK) if M=P/Q, and P and Q aremutually prime integers.

Since the phase index l is solved and Δθ=lδϕ, the phase Δθ is solved.While the phase index l is solved, the L first frequency signals withthe L different first phases (i.e. B cos(ωreft), B cos(ωreft+Δθ), Bcos(ωreft+2Δθ), . . . , B cos(ωreft+(L−1)Δθ)) can be determined, theswitching box 311 can select the L first frequency signals with the Ldifferent first phases among the K frequency signals with the Kdifferent first phases (i.e. B cos(ωreft), B cos(ωreft+δϕ), Bcos(ωreft+2δϕ), . . . , B cos(ωreft+(K−1)δϕ).

One implementation of the switching box 311 is shown in FIG. 4, and thepresent disclosure is not limited thereto. Referring to FIG. 4, FIG. 4is a circuit diagram of a switching box according to an embodiment ofthe present disclosure. The switching box 4 is a read-only memory (ROM),and comprises a plurality of switches r0 through rLK−1, a plurality ofinput lines IN_0 through IN_K−1 and a plurality of output lines OUT_0through OUT_L−1. First ends of the switches rnK through r(n+1)K−1 areconnected to the output line OUT_n, and second ends of the switchesr_(nK) through r(n+1)K−1 are connected to the input lines IN_0 throughIN_K−1. The control signals are used to control the switches r0 throughrLK−1 to be turned on or off, such that the input lines IN_1 throughIN_K−1 receive the K first frequency signals with the K different firstfrequencies, and the output lines OUT_1 through OUT_L−1 outputs theselected L first frequency signals with the selected L different firstfrequencies.

Next, referring to FIG. 5, FIG. 5 is a block diagram of a multi-phasesignal generating circuit according to an embodiment of the presentdisclosure. The multi-phase signal generating circuit 5 comprises avoltage controlled delay line 51, a phase detector 52 and a LPF 53,wherein the voltage controlled delay line 51 is connected to the LPF 53and the phase detector 52, and the phase detector 52 is connected to theLPF 53.

The voltage controlled delay line 51 has a plurality of delay unitsconnected in series, and the delay time of the delay units is controlledby the output signal of the LPF 53. A reference clock signal REF_CLK isinput to the voltage controlled delay line 51 and the phase detector 52,and the phase detector 52 compares the phases of the reference clocksignal REF_CLK and the output signal of the last delay unit of thevoltage controlled delay line 51, so as to output a comparison signal.The LPF 53 filters out the high frequency part of the comparison signal.The input ends of the delay units are used to output the K firstfrequency signals with the K different first phases (i.e. B cos(ωreft),B cos(ωreft+δϕ), B cos(ωreft+2δϕ), . . . , B cos(ωreft+(K−1)δϕ)).

It is noted that the implementation of multi-phase signal generatingcircuit 5 is not used to limit the present disclosure. Next, refereeingto FIG. 6, FIG. 6 is a block diagram of a multi-phase signal generatingcircuit according to another one embodiment of the present disclosure.The multi-phase signal generating circuit 6 comprises a phase-frequencydetector (PFD), a charge pump 62, a loop filter 63, a quadrature VCO(QVCO) 64, a frequency divider 65 and an injection-lock-frequencydivider (ILFD) 66. The PFD 61 is connected to the frequency divider 65,the charge pump 62 is connected to the loop filter 63, the loop filter63 is connected to the QVCO 64, the QVCO 64 is connected to the ILFD 66and the frequency divider 65.

The PFD 61 receives a reference clock signal REF_CLK and a frequencydivided signal from the frequency divider 65 with a divisor of K/4. ThePFD 61 compares frequencies and phases of the reference clock signalREF_CLK and the frequency divided signal to output a comparison signalto the charge pump 62. The charge pump 62 raises the voltage of thecomparison signal. The loop filter 63 filters the output signal of thecharge pump 62, and the QVCO 64 receives the output signal of the loopfilter 63 to output oscillating signals with quadrature phases. Thefrequency divider 65 receives one of the oscillating signals withquadrature phases, and divides the frequency of the received oscillatingsignal. The ILFD 66 is a 4-to-K ILFD, and receives the oscillatingsignals with the quadrature phases to generate the K first frequencysignals with the K different first phases (i.e. B cos(ωreft), Bcos(ωreft+δϕ), B cos(ωreft+2δϕ), . . . , B cos(ωreft+(K−1)δϕ)).

FIG. 7 is a flow chart of a phase controlling method for an antennaarray according to an embodiment of the present disclosure. The phasecontrolling method is executed in a communication apparatus which has aplurality of antennae forming an antenna array, wherein thecommunication apparatus can be the receiver, the transmitter or thetransceiver. At step S71, a direction index k is determined according tothe phase of the antenna array. Then at step S72, a phase index l iscalculated according the direction index k based upon the abovecongruence modulo equation.

At step S73, L first frequency signals with L different first phases areselected from K first frequency signals with K different first phasesaccording to the phase index l. Then, at step S74, L second frequencysignals with L different second phases are generated according to the Lfirst frequency signals with the selected L different first phases byusing L phase-coherent PLL frequency synthesizers. Next, at step S75,the L second frequency signals with the selected L different secondphases are output to L antenna to control a radiation field pattern ofthe antenna array via L front-end circuits.

Next, referring FIG. 8A and FIG. 8B, FIG. 8A and FIG. 8B are schematicdiagrams of radiation field patterns of antenna array with differentdirection indices while the phase controller or phase controlling methodfor the antenna array according to an embodiment of the presentdisclosure is used. In this embodiment, the conditions are given asfollows: M=181, K=64, L=16, k=14 for FIG. 8A, and k=−14 (or 50) for FIG.8B.

In FIG. 8A, since the direction index k is 14, the solved phase index lbased upon the congruence equation Ml≡k(mod K) is 22, and thus theselected 16 first phases ϕin of the 16 first frequency signals and thesecond phases ϕout of the 16 second frequency signals is shown in Table1 (p.s. the above phase are presented by the remainders of 2π). Theradiation field pattern in FIG. 8A shows the phase of the antenna arrayis about 60 degrees.

TABLE 1 ϕ_(out) 0 14π/32 28π/32 42π/32 56π/32  6π/32 20π/32 ϕ_(in) 022π/32 44π/32  2π/32 24π/32 46π/32  4π/32 ϕ_(out) 34π/32 48π/32 62π/3212π/32 26π/32 40π/32 54π/32 ϕ_(in) 26π/32 48π/32  6π/32 28π/32 50π/32 8π/32 30π/32 ϕ_(out)  4π/32 18π/32 NA NA NA NA NA ϕ_(in) 52π/32 10π/32NA NA NA NA NA

In FIG. 8B, since the direction index k is −14, the solved phase index lbased upon the congruence equation Ml≡k(mod K) is −22, and thus theselected 16 first phases ϕin of the 16 first frequency signals and thesecond phases ϕout of the 16 second frequency signals is shown in Table2 (p.s. the above phase are presented by the remainders of 2π). Theradiation field pattern in FIG. 8B shows the phase of the antenna arrayis about 300 degrees.

TABLE 2 ϕ_(out) 0 50π/32 36π/32 22π/32  8π/32 58π/32 44π/32 ϕ_(in) 042π/32 20π/32 62π/32 40π/32 18π/32 60π/32 ϕ_(out) 30π/32 16π/32  2π/3252π/32 38π/32 24π/32 10π/32 ϕ_(in) 38π/32 16π/32 58π/32 36π/32 14π/3256π/32 34π/32 ϕ_(out) 60π/32 46π/32 NA NA NA NA NA ϕ_(in) 12π/32 54π/32NA NA NA NA NA

In collusion, the present disclosure is used to provide a communicationapparatus having a phase controller or executing a phase controllingmethod for an antenna array with a plurality of antennae, so as to havethe low phase and amplitude error, the high frequency precision and thecorrect desired radiation field pattern.

While the present disclosure has been described by means of specificembodiments, numerous modifications and variations could be made theretoby those skilled in the art without departing from the scope and spiritof the present disclosure set forth in the claims.

What is claimed is:
 1. A phase controller for an antenna array, comprising: a determination circuit, determining a direction index of the antenna array, and calculating a phase index according to the direction index according to a congruence modulo equation; a switching box, connected to the determination circuit, selecting L first frequency signals with L different first phases among K first frequency signals with K different first phases according to the phase index, wherein L and K are integer larger than 1, and L is not larger than K; and a frequency synthesizing module, connected to the switching box, comprising L phase-coherent PLL frequency synthesizers for receiving the L first frequency signals with the L different first phases to generate L second frequency signals with L different second phases to L antennae of the antenna array, wherein a second frequency of the second frequency signals is larger than a first frequency of the first frequency signals; wherein the switching box comprises: a plurality output lines IN_0, IN_1, . . . , IN_K−1; a plurality of input lines OUT_0, OUT_1, . . . , OUT_K−1; and a plurality of switches r₀, r₁, r₂, . . . , r_(LK-1), first ends of the switches r_(nK) through r_((n+1)K-1) are connected to the output line OUT_n, and second ends of the switches r_(nK) through r_((n+1)K-1) are connected to the input lines IN_0 through IN_K−1, wherein n is an integer from 0 through L−1; wherein the switches r₀, r₁, r₂, . . . , r_(LK-1) are turned on or off according to the phase index, so as to select the L first frequency signals with the L different first phases among the K first frequency signals with the K different first phases; wherein the phase-coherent PLL frequency synthesizer comprises: a mixer, receiving a corresponding one of the L first frequency signals with the L different first phases and a frequency divided signal; a low pass filter, connected to the mixer, filtering an output signal of the mixer; a voltage controlled oscillator, connected to the low pass filter, generating a corresponding one of the L second frequency signals with the L different second phases according to a control voltage output from the low pass filter; and a frequency divider, connected to the mixer and the voltage controlled oscillator, generating the frequency divided signal according to the corresponding second frequency signal with the second phase.
 2. The phase controller for the antenna array according to claim 1, wherein the K different first phases are 0, δϕ, 2δϕ, . . . , (K−1)δϕ, the L different first phases are 0, Δθ, 2Δθ, . . . , (L−1)Δθ, the second different phases are 0, Δϕ, 2Δϕ, . . . , (L−1)Δϕ, δϕ is a phase resolution and equals to 2π/K, Δϕ equals to kδϕ, k is the direction index being an integer, Δθ equals to lδϕ, l is the phase index being an integer, and the congruence equation is Ml≡k(mod K) if M and K are mutually prime integers, wherein M is a frequency divisor.
 3. The phase controller for the antenna array according to claim 1, wherein the K different first phases are 0, δϕ, 2δϕ, . . . , (K−1)δϕ, the L different first phases are 0, Δθ, 2Δθ, . . . , (L−1)Δθ, the second different phases are 0, Δϕ, 2Δϕ, . . . , (L−1)Δϕ, δϕ is a phase resolution and equals to 2π/K, Δϕ equals to kδϕ, k is the direction index being an integer, Δθ equals to lδϕ, l is the phase index being an integer, and the congruence equation is Pl≡Qk(mod QK) if M=P/Q, and P and Q are mutually prime integers, wherein M is a frequency divisor.
 4. The phase controller for the antenna array according to claim 1, wherein the direction index is related to a phase, a main radiating direction and a radiation field pattern of the antenna array.
 5. A communication apparatus, comprising: a multi-phase signal generating circuit, providing K first frequency signals with K different first phases; L antennae, forming an antenna array; and a phase controller for the antenna array, connected between the multi-phase signal generating circuit and the L antennae, comprising: a determination circuit, determining a direction index of the antenna array, and calculating a phase index according to the direction index according to a congruence modulo equation; a switching box, connected to the determination circuit, selecting L first frequency signals with L different first phases among the K first frequency signals with the K different first phases according to the phase index, wherein L and K are integer larger than 1, and L is not larger than K; and a frequency synthesizing module, connected to the switching box, comprising L phase-coherent PLL frequency synthesizers for receiving the L first frequency signals with the L different first phases to generate L second frequency signals with L different second phases to the L antennae of the antenna array, wherein a second frequency of the second frequency signals is larger than a first frequency of the first frequency signals wherein the switching box comprises: a plurality output lines IN_0, IN_1, . . . , IN_K−1; a plurality of input lines OUT_0, OUT_1, . . . , OUT_K−1; and a plurality of switches r₀, r₁, r₂, . . . , r_(LK-1), first ends of the switches r_(nK) through r_((n+1)K-1) are connected to the output line OUT_n, and second ends of the switches r_(nK) through r_((n+1)K-1) are connected to the input lines IN_0 through IN_K−1, wherein n is an integer from 0 through L−1; wherein the switches r₀, r₁, r₂, . . . , r_(LK-1) are turned on or off according to the phase index, so as to select the L first frequency signals with the L different first phases among the K first frequency signals with the K different first phases; wherein the phase-coherent PLL frequency synthesizer comprises: a mixer, receiving a corresponding one of the L first frequency signals with the L different first phases and a frequency divided signal; a low pass filter, connected to the mixer, filtering an output signal of the mixer; a voltage controlled oscillator, connected to the low pass filter, generating a corresponding one of the L second frequency signals with the L different second phases according to a control voltage output from the low pass filter; and a frequency divider, connected to the mixer and the voltage controlled oscillator, generating the frequency divided signal according to the corresponding second frequency signal with the second phase.
 6. The communication apparatus according to claim 5, wherein the K different first phases are 0, δϕ, 2δϕ, . . . , (K−1)δϕ, the L different first phases are 0, Δθ, 2Δθ, . . . , (L−1)Δθ, the second different phases are 0, Δϕ, 2Δϕ, . . . , (L−1)Δϕ, δϕ is a phase resolution and equals to 2π/K, Δϕ equals to kδϕ, k is the direction index being an integer, Δθ equals to lδϕ, l is the phase index being an integer, and the congruence equation is Ml≡k(mod K) if M and K are mutually prime integers, wherein M is a frequency divisor.
 7. The communication apparatus according to claim 5, wherein the K different first phases are 0, δϕ, 2δϕ, . . . , (K−1)δϕ, the L different first phases are 0, Δθ, 2Δθ, . . . , (L−1)Δθ, the second different phases are 0, Δϕ, 2Δϕ, . . . , (L−1)Δϕ, δϕ is a phase resolution and equals to 2π/K, Δϕ equals to kδϕ, k is the direction index being an integer, Δθ equals to lδϕ, l is the phase index being an integer, and the congruence equation is Pl≡Qk(mod QK) if M=P/Q, and P and Q are mutually prime integers, wherein M is a frequency divisor.
 8. The communication apparatus according to claim 5, wherein the multi-phase signal generating circuit comprises: a voltage controlled delay line, having a plurality of delay units connected in series, receiving a reference clock signal; a phase detector, connected to the voltage controlled delay line, comparing phases of the reference signal and an output signal of the voltage controlled delay line to output a comparison signal; and a low pass filter, connected to the phase detector and the voltage controlled delay line, filtering the comparison signal; wherein a delay time of the delay units is controlled by an output signal of the low pass filter, and input ends of the delay units are used to output the K first frequency signals with the K different first phases.
 9. The communication apparatus according to claim 5, wherein the multi-phase signal generating circuit comprises: a phase-frequency detector, receiving a reference clock signal and a frequency divided signal, and comparing frequencies and phases of the reference clock signal and the frequency divided signal to output a comparison signal; a charge pump, connected to the phase-frequency detector, raising a voltage of the comparison signal; a loop filter, connected to the charge pump, filtering an output signal of the charge pump; a quadrature voltage controlled oscillator, connected to the loop filter, receiving an output signal of the loop filter to generate oscillating signal with quadrature phases; a frequency divider, connected to the quadrature voltage controlled oscillator, receiving one of the oscillating signal with the quadrature phases to generate the frequency divided signal; and an injection-locked frequency divider, connected to the quadrature voltage controlled oscillator, receiving the oscillating signals with the quadrature phases to generate the K first frequency signals with the K different first phases.
 10. The communication apparatus according to claim 5, further comprising: a L-path front-end circuit module, comprising L front-end circuits, wherein the front-end circuit comprises: a mixer, mixing a transmitted intermediate frequency signal with a corresponding one of the L second frequency signals with the L different second phases; a filter, connected to the mixer, filtering an output signal of the mixer; and a power amplifier, connected to the filter, amplifying an output signal of the filter, so as to generate an output signal to the corresponding antenna.
 11. The communication apparatus according to claim 5, wherein the communication apparatus is a receiver, a transmitter or a transceiver.
 12. The communication apparatus according to claim 5, wherein the direction index is related to a phase, a main radiating direction and a radiation field pattern of the antenna array.
 13. A phase controlling method for an antenna array, comprising: determining a direction index of the antenna array; calculating a phase index according to the direction index according to a congruence modulo equation; selecting L first frequency signals with L different first phases among K first frequency signals with K different first phases according to the phase index, wherein L and K are integer larger than 1, and L is not larger than K; and generating L second frequency signals with L different second phases to L of antennae of the antenna array according to the L first frequency signals with the L different first phases by using L phase-coherent PLL frequency synthesizers, wherein a second frequency of the second frequency signals is larger than a first frequency of the first frequency signals; wherein the K different first phases are 0, δϕ, 2δϕ, . . . , (K−1)δϕ, the L different first phases are 0, Δθ, 2Δθ, . . . , (L−1)Δθ, the second different phases are 0, Δϕ, 2Δϕ, . . . , (L−1)Δϕ, δϕ is a phase resolution and equals to 2π/K, Δϕ equals to kδϕ, k is the direction index being an integer, Δθ equals to lδϕ, and l is the phase index being an integer; wherein the congruence equation is Ml≡k(mod K) if M and K are mutually prime integers, wherein M is a frequency divisor; the congruence equation is Pl≡Qk(mod QK) if M=P/Q, and P and Q are mutually prime integers; wherein the direction index is related to a phase, a main radiating direction and a radiation field pattern of the antenna array. 